Type one diabetes (T1D: (juvenile onset) whilst being a chronic disease, the defining
feature of which is the destruction of the insulin-secreting beta-cells and subsequent
dependence on exogenous insulin, is possessing with hallmark characteristics of the
complex T cell-mediated autoimmunity superimposed on genetic susceptibility. Both
genetic and environmental factors combine to precipitate disease, and the outcome
of the pathological process is dependent on multiple interrelated factors. The annual
global incidence of T1D is increasing by 3-5% per year.
Both HLA-genes and immune markers (autoantibodies/autoAbs) have been validated as
predictive biomarkers of the subsequent development of the disease in higher-risk
relatives and the lower-risk general population. Over the last three decades, using
a combination of genomic, proteomic, and metabolomic biomarkers, clinicians are now
able to quantify an individual's disease risk from 1 in 100,000 to more than 1 in
2. The HLA genes are reported to account for approximately 40-50% of the familial
aggregation of T1D.
Current approaches for the prediction of T1D in screening studies take advantage of
genotyping HLA-DR and HLA-DQ loci, which is then combined with family history and
screening for autoAbs directed against islet-cell Ags. Inclusion of additional moderate
HLA risk haplotypes may help identify the majority of children withT1D before the
onset of the disease. Fine mapping and functional studies are gradually revealing
the complex mechanisms whereby immune self-tolerance is lost, involving adaptive immunity.
Genetic prediction of T1D risks is showing promise of use for preventive strategies.
And understanding of the genetics, environmental factors, and natural history of T1D
has resulted in greater understanding of the etiology and epidemiology of the disease.
The clinical care of patients with T1D has greatly improved over the past few decades;
however, it remains impossible to completely normalize blood sugar utilizing currently
available tools. Meanwhile, subclinical and predictive diagnostic armamentarium is
still far from being unique, and innovative algorithms that significantly differ from
the clinical approaches should become the major bricks to be laid into the basis of
a subclinical diagnosis of pre-T1D.
Generally, there are three levels desirable for an optimal pre-T1D and T1D-related
healthcare, namely,
(i) 1st level: prediction of the familial predisposition, targeted prevention of pre-T1D
early in childhood;
(ii) 2nd level: prediction of early/premature aging and targeted prevention of T1D-related
pre-stages;
(iii) 3rd level: prediction of secondary complications in the cohort of T1D-patients
and creation of personalized treatment modes tailored to the patient to prevent post-T1D
complications frequently developed.
Accurate prediction is vital for T1D prevention so that preventive treatment can be
given to those individuals who are most likely to develop the disease. Predictive
medicine is intended more so for healthy individuals, its purpose being to determine
whether susceptibility to a particular disease is increased or not. And the long asymptomatic
period before the onset of clinical T1D offers good opportunities for disease prevention.
And preventive portion of PPPM (or preventive care) refers to measures taken to prevent
diseases rather than curing them or treating their symptoms. Indeed, many chronic
diseases like T1D may be preventable by avoiding those factors that trigger the disease
process (primary prevention) or by use of treatment modes that modulate the disease
process before the onset of clinical symptoms (secondary prevention).
The utility of predictive biomarkers to monitor T1D-related stages and to predict
the transitions is dependent on three key parameters, which must be carefully assessed:
sensitivity, specificity and positive predictive value. Recent advances in genomics,
proteomics, and bioinformatics offer a great opportunity for biomarker discovery,
and the newly identified biomarkers and biopredictors have the potential to bring
increased accuracy in T1D diagnosis and classification, as well as personalized therapeutic
monitoring. The latter including efficacious quenching of autoimmune insulitis (pre-T1D)
and prevention of clinical T1D will require detection of the earliest events in the
process. But currently, there is no effective treatment strategy to restore glucose
regulation in T1D patients. So, personalized medicine is a medical model that proposes
the customization of healthcare, with all decisions and practices being tailored to
the individual T1D patient by use of genetic or other information.
So far, antiislet autoAbs are most widely used as serum biomarker in making and verifying
the diagnosis of subclinical and clinical stages of T1D, but T-cell readouts and metabolome
studies might strengthen and bring forward diagnosis. The autoAbs can be detected
before (as early as 5-10 years before the clinical onset) and at time of clinical
diagnosis of disease and could thus be used to predict risks of developing T1D in
first degree relatives of probands.
Monotherapy for T1D has not resulted in sustained tolerance and preservation of C-peptide
production; individuals still progress to a complete loss of endogenous insulin producing
ability. Combination therapy is likely to be necessary as different pathways and arms
of the immune system can be targeted. However, current preventive clinical trials
mostly focus on environmental triggers. At the same time, there is an immediate need
to restore both beta-cell function and immune tolerance to control disease progression
and ultimately cure T1D, and so, the strategy of prevention of pre-T1D-T1D transition
should contain two critical points, i.e., (i) obligatory arrest/blockage of autoagression
and (ii) restoration of beta-cell infrastructure and function. As it is evident, strategies
for disease intervention, therefore, will not only require the induction of T-cell
tolerance by tipping the balance towards regulation but will also need to contain
approaches that result in the scavenging of inflammatory mediators, in order to facilitate
repair.
For instance, efficiently halting immune attack in the islet milieu by an effector-specific
manner apparently provides the preventive and therapeutic strategies in T1D. For instance,
FoxP3-expressing CD4+ Tregs are potential candidates to control autoimmunity because
they play a central role in maintaining self-tolerance.
Preservation and/or restoration of structural architectonics and function of beta
cells can be accomplished by the use of (i) immune, cell-based and/or gene therapy
(e.g., islet transplantation could be an appropriate treatment to accomplish insulin
independence and long-term homeostasis of glucose in T1D), and (ii) regenerative drug-based
treatment including stem cell (SC) technologies. Tremendous progress has been made
in the field of islet regeneration in the past few years, and beta-cell replacement
by islet transplantation and/or SCs has provided new hope for a cure of T1D.
However, it is difficult to protect the islet grafts or beta-cells restored from subsequent
immune attack and prolong their survival. The optimal therapeutic approach for T1D
in this connection should ideally preserve the remaining β-cells, restore β-cell function,
and protect the replaced insulin-producing cells from autoimmunity. SCs possess unique
immune and restorative properties that could be harnessed to improve the treatment
of T1D; indeed, SCs may re-establish peripheral tolerance toward β-cells through reshaping
of the immune response and inhibition of autoreactive CTCs.
Along with combination therapy, we believe targeted and specific immune therapies
are needed to prevent and ultimately cure T1D. Those therapies can be designed to
specifically target insulin-HLA complexes and the TCRs that recognize them. Small
molecule approaches can block autoAg presentation or TCR recognition of autoAg-HLA
complexes. Another strategy includes designing MAbs to recognize autoAg peptide-HLA
complexes with the peptide in a defined register recognized by the autoreactive TCRs.
As the structural basis of autoAg presentation and T cell recognition advances, these
novel approaches become realistic. There is thus a requirement for an increased, collaborative
effort between clinical endocrinologists, specialists in PPPM, stem cell biologists
and immunologists in order to tailor an optimal and personalized therapeutic strategy
for the treatment of this debilitating disease.
Moreover, implementation of PPPM program requires the adjusted technology for adequate
interpretation of diagnostic data before the current model “physician-patient” could
be gradually displaced by a novel model “medical advisor-healthy men-at-risk”. Systemic
approach to formation of an innovative infrastructure regarding prediction and prevention
algorithms is an ultimate approach that will contribute to modernization of T1D-related
healthcare significantly. An understanding and possibly a complete description of
the factors underlying the burden of T1D will provide policy-makers, healthcare providers
and mentors with an opportunity to guide primary and secondary preventive initiatives
at both individual and community levels. Our challenge is that new guidelines should
create the robust juristic and economic platform for advanced medical services utilizing
the cost-effective models of risk assessments followed by tailored preventive and
personalized treatments focused on the precursor stages of T1D. What is a realistic
timeline for the incorporation of PPPM into the practice of endocrinology and T1D,
in particular? Patients and relatives alike want interventions that work right now.
And PPPM would thus promise to sharply reverse the ever escalating costs of T1D-related
diagnosis and treatment to stratify patients and disease, less expensive approaches
to drug discovery, preventive medicine and wellness. PPPM also promises to improve
T1D patient outcomes, and to empower both the patient and the physician.